Chip sorting devices and related assemblies, components and methods

ABSTRACT

Chip sorting devices may include at least one chip collection tube having at least one adjustable wall that at least partially defines an inner diameter of the at least one chip collection tube. The at least one adjustable wall may be at least partially rotatable to define different inner diameters. Chip sorting devices may include a chip hopper having a relief mechanism for clearing chips that become jammed between a chip chamber and a base plate of the chip hopper. Methods of sorting chips may include actuating the relief mechanism to increase a space between a top plate of the relief mechanism and the chip chamber. Methods of setting up a chip sorting device may include adjusting an inner lateral dimension of the at least one chip collection tube.

TECHNICAL FIELD

The disclosure relates to chip sorting devices and related assemblies,components and methods. In particular, embodiments of the disclosurerelate to chip sorting devices, collecting tubes for chip sortingdevices, chip jam clearing systems, and methods of sorting chips.

BACKGROUND

Given the desire to improve profitability and increase the speed andefficiency of table game play in gaming establishments, there is a needto reduce costs through cost savings and replacement costs due to wearand tear on equipment. Furthermore, given the desire to improveprofitability and increase the speed and efficiency of game play ingaming establishments, there is a need to increase the number of roundsthat may be played with gaming equipment in a selected amount of time,decrease the amount of work performed by human dealers, etc. Forexample, there is a need for improved chip sorting devices, which mayhave the same or similar profile as existing equipment to avoidretrofitting existing gaming tables and that include adjustablepositioning structures to permit limited movement of the device adjacentthe gaming table surface. Additionally, it may be desirable to developimproved chip sorting devices having reduced production cost, which mayimprove efficiency, improve reliability, reduce wear on chips andminimize noise to preserve the casino ambience. Furthermore, it may bedesirable to develop improved chip sorting devices that are easilycustomizable to accommodate varying chip sizes. Finally, it may bedesirable to develop improved chip sorting devices having jammed chipclearing features in order to improve reliability of the chip sortingdevices.

BRIEF SUMMARY

This summary is provided to introduce a selection of exemplaryembodiments in a simplified form. These exemplary embodiments aredescribed in further detail in the detailed description below. Thissummary is not intended to identify key features or essential featuresof the claimed subject matter, nor is it intended to be used to limitthe scope of the claimed subject matter.

Some embodiments of the present disclosure include a chip sortingdevice. The chip sorting device may include a chip conveyor unit havingat least one chip well for transporting chips, at least one chipcollection tube, and at least one chip ejection unit. The at least onechip collection tube may have an inner lateral dimension defined thereinfor receiving at least one chip therein. The at least one chipcollection tube may include at least one frame assembly; and at leastone adjustable wall coupled to the at least one frame assembly and atleast partially defining the inner lateral dimension of the at least onechip collection tube. At least a portion of the at least one adjustablewall may be rotatable relative to the at least one frame assembly inorder to selectively increase and decrease the inner lateral dimensionof the at least one chip collection tube. The at least one chip ejectionunit may be configured and positioned to eject at least one chip fromthe at least one chip well of the chip conveyor unit into the at leastone chip collection tube.

Some embodiments of the present disclosure include a chip sortingdevice. The chip sorting device may include a chip hopper and a chipconveyor unit. The chip hopper may include a base plate, a chip chambermounted over the base plate and rotatable about a center axis relativeto the base plate, and a relief mechanism. The chip chamber may includea separating wheel base defining a plurality of circular holesconfigured to receive at least one chip therein. The relief mechanismmay have a top plate having a top surface oriented at leastsubstantially flush with an upper surface of the base plate. The reliefmechanism may be configured to move away from the chip chamber. The chipconveyor unit may include at least one chip well configured to receive achip therein from the chip hopper.

Some embodiments of the present disclosure include methods of sortingchips. The methods may include inserting at least one chip into a chipchamber of a chip hopper rotatably mounted over of a base plate of thechip hopper, receiving the at least one chip into a hole of a pluralityof circular holes defined in a separating wheel base of the chipchamber, transporting the at least one chip along a circumferential pathon an upper surface of the base plate of the chip hopper, and increasingspace between the chip chamber and a top plate of a relief mechanism bymoving the top plate of the relief mechanism away from the chip chamberand relative to the base plate of the chip hopper.

Some embodiments of the present disclosure include methods of setting upa chip sorting device. The methods may include adjusting an innerlateral dimension of at least one chip collection tube of the chipsorting device to accommodate at least one chip. Adjusting an innerlateral dimension of at least one chip collection tube to accommodate atleast one chip may include rotating an adjustment mechanism of the atleast one chip collection tube relative to a frame assembly of the atleast one chip collection tube and rotating at least one adjustable wallinto an interior of the frame assembly of the at least one chipcollection tube, the at least one adjustable wall defining at least aportion of the inner lateral dimension of the at least one chipcollection tube.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure may be understood more fully by reference to thefollowing detailed description of example embodiments, which areillustrated in the accompanying figures.

FIG. 1 shows a perspective view of a chip sorting device, according toan embodiment of the present disclosure, with portions of housingsremoved to show interior components of the chip sorting device.

FIG. 2 shows a top elevation of the chip sorting device of FIG. 1 havingadditional portions of housings removed to show interior components ofthe chip sorting device.

FIG. 3 shows a perspective view of a chip ejection unit of the chipsorting device of FIG. 1.

FIG. 4A shows a perspective view of a chip collection tube of the chipsorting device of FIG. 1 having portions removed to show a firstplurality of adjustable walls within the chip collection tube.

FIG. 4B shows a top elevation of the chip collection tube of FIG. 4Ahaving portions removed to show the first plurality of adjustable wallswithin the chip collection tube.

FIG. 4C shows another top elevation of the chip collection tube of FIG.4A having portions removed to show the first plurality of adjustablewalls within the chip collection tube.

FIG. 5A shows a perspective view of a plunger assembly of the chipsorting device of FIG. 1 having portions removed to show the plunger andactuation assembly of the plunger assembly.

FIG. 5B shows a top elevation of the chip collection tube of FIG. 4Ahaving portions removed to show a head portion of the plunger within thechip collection tube.

FIG. 5C shows a side view of the plunger assembly of FIG. 5A in anextended orientation.

FIG. 6A shows a perspective view of the chip collection tube of FIG. 4Awith additional portions shown.

FIG. 6B shows a perspective view of a second frame assembly and a secondplurality of adjustable walls of the chip collection tube.

FIG. 6C shows a top elevation of the frame assembly and the secondplurality of adjustable walls of FIG. 6B.

FIG. 7A shows a perspective view of a chip hopper of the chip sortingdevice of FIG. 1.

FIG. 7B shows a perspective view of a base plate of the chip hopper ofFIG. 7A with portions removed to show a relief mechanism of the chiphopper.

DETAILED DESCRIPTION

The illustrations presented herein are not meant to be actual views ofany particular chip sorting device, or component thereof, but are merelysimplified schematic representations employed to describe illustrativeembodiments of the disclosure. The drawings are not necessarily toscale.

Some embodiments of the present disclosure may include chip sortingdevices having chip collection tubes having variable inner lateraldimensions or areas (e.g., diameters, cross-sectional areas, etc.). Inother words, the inner diameters, or one or more components definingeffective inner diameters, of the chip collection tubes may be adjustedto accommodate different sized chips. Some embodiments of the presentdisclosure may include sorting devices having chip collection tubes thathave a plurality of adjustable walls that define the inner diameters,and the adjustable walls may be rotatable within the chip collectiontubes to change the inner diameters of the chip collection tubes. Someembodiments of the present disclosure include chip sorting deviceshaving chip hoppers, which may include relief mechanisms for clearingchips positioned (e.g., jammed) between various portions of the chipsorting device (e.g., between portions of a chip hopper. The reliefmechanism may provide an increased space for the jammed chips to enablethe jammed chips to be removed and delivered to a chip conveyor unit.

As used herein, any relational term, such as “first,” “second,” “over,”“beneath,” “top,” “bottom,” “underlying,” “up,” “down,” etc., is usedfor clarity and convenience in understanding the disclosure andaccompanying drawings, and does not connote or depend on any specificpreference, orientation, or order, except where the context clearlyindicates otherwise. For example, these terms may refer to anorientation of elements of the chip sorting device relative to a surfaceof a table beneath which the chip sorting device may be positioned andoperated (e.g., as illustrated in the figures).

As used herein, the terms “vertical” and “horizontal” may refer to adrawing figure as oriented on the drawing sheet, and are in no waylimiting of orientation of an apparatus, or any portion thereof, unlessit is apparent that a particular orientation of the apparatus isnecessary or desirable for operation in view of gravitational forces.For example, when referring to elements illustrated in the figures, theterms “vertical” or “horizontal” may refer to an orientation of elementsof the chip sorting device relative to a surface of a table beneathwhich the chip sorting device may be positioned and operated.

A perspective view of a chip sorting device 100 with portions of one ormore housings of the chip sorting device 100 removed to show interiorcomponents of the chip sorting device 100 is shown in FIG. 1. The chipsorting device 100 may be positioned beneath a table surface (e.g., agaming table surface) of a table (e.g., a gaming table) and to deliversorted chips to the table surface and/or receive chips to be sorted fromthe table surface. As shown, the chip sorting device 100 may comprise aframe structure 102, a chip hopper 104, a chip conveyor unit 106, aplurality of chip ejection units 108, and a plurality of chip collectiontubes 110. The chip hopper 104 may be oriented at least partially overthe chip conveyor unit 106 and any chips sorted by the chip hopper 104may be moved (e.g., dropped) from the chip hopper 104 onto the chipconveyor unit 106. The plurality of chip ejection units 108 and theplurality of chip collection tubes 110 may be disposed adjacent to thechip conveyor unit 106 along a length of the chip conveyor unit 106.

FIG. 2 is a top elevation of the chip sorting device 100 with portionsof housings removed to more clearly show interior components of the chipsorting device 100. The chip conveyor unit 106 may include anarticulated conveyor 202, which may be arranged along a fixed pathwithin the chip sorting device 100. The articulated conveyor 202 maycomprise a plurality of articulated link units 204 and each link unit204 may include a chip well 206 for carrying at least one chip 208. Eachchip well 206 may be at least partially defined by and positionedadjacent to segmented guide walls 210 comprised of a plurality of wallsegments 212, and a plurality of channels 214 may be defined betweenwall segments 212 of the plurality of wall segments 212.

The fixed path of the articulated conveyor 202 may enable each link unit204, and any chips 208 that may be carried thereby, to travel along agenerally straight path (i.e., a substantially linear path) whenproximate to the chip hopper 104. The fixed path may enable each linkunit 204, and any chips 208 that may be carried thereby, to travel alonga generally curved path when proximate to the plurality of chip ejectionunits 108 and corresponding plurality of chip collection tubes 110. Insome embodiments, a drive belt 216 of the chip conveyor unit 106 may beat least partially formed from a nonmetal material (e.g., not a metalchain drive belt). For example, the drive belt 216 may be formed from aflexible polymer material, internally fiber-reinforced as desirable,that may require little to no maintenance (e.g., may not requireregularly scheduled lubrication).

In some embodiments, the chip sorting device 100 may include a liftingmechanism configured to lift chip sorting device 100 relative to a tableto which the chip sorting device 100 may be positioned under. In someembodiments, the lifting mechanism may be operated pneumatically. Inother embodiments, the lifting mechanism may be operated electrically.

FIG. 3 is a perspective view of a chip ejection unit 108 of theplurality of chip ejection units 108 of a chip sorting device (e.g., thechip sorting device 100 shown in FIGS. 1 and 2). In some embodiments,the chip sorting device 100 may include chip ejections units asdescribed in U.S. Pat. No. 8,336,699 to Blaha et al., the disclosure ofwhich is incorporated in its entirety by this reference. For example,each chip ejection unit 108 may include finger members 302, 304, 306,308 sized and positioned to be positioned adjacent and/or between one ormore wall segments 212 of the plurality wall segments 212 and into theplurality of channels 214. In other words, the finger members 302, 304,306, 308 of the chip ejection units 108 may be positioned axially overthe plurality of channels 214 and may be selectively movable into theplurality of channels 214. The finger members 302, 304, 306, 308 mayoperate in the same manner as the finger members 302 of the chipejection units described in U.S. Pat. No. 8,336,699 to Blaha et al. toeject selected chips 208 into selected chip collection tubes 110according to different chip classifications. For example, each chipejection unit 108 of the plurality of chip ejection units 108 mayinclude a motor 310, such as one of a stepper motor and a servomotor,attached to a cam shaft 312 supporting a plurality of cams 314, such astri-lobe cams, thereon. The cams 314 may be oriented to move each of thefinger members 302, 304, 306, 308 from a first position to a secondposition, and back to the first position, in a sequence by rotation ofthe cam shaft 312 with the motor 310. For example, the cams 314 may beoriented to lower the finger members 302, 304, 306, 308 into alignmentwith the plurality of channels 214 to block a pathway of a chip 208(FIG. 2) being transported in a chip well 206 (FIG. 2) of the chipconveyor unit 106 in order to move the chip 208 toward a respective chipcollection tube 110.

FIG. 4A is a top perspective view of a chip collection tube 110 of theplurality of chip collection tubes 110 of the chip sorting device 100(FIG. 1) with portions removed to more clearly show internal componentsthereof. FIG. 4B is a top elevation of the chip collection tube 110 ofFIG. 4A with portions removed to more clearly show components thereof.FIG. 4C is a top elevation of the chip collection tube 110 of FIG. 4Awith portions removed to more clearly show components thereof. Referringto FIGS. 4A-4C together, the chip collection tube 110 may include afirst frame assembly 402, a first plurality of adjustable walls 404, afirst adjustment mechanism 406, and an inner lateral dimension (e.g., aninner diameter 408) that is at least partially defined by the firstplurality of adjustable walls 404. The first frame assembly 402 mayinclude a first tubular portion 410 where a chip 208 may be receivedinto the chip collection tube 110 from the chip conveyor unit 106 (FIG.1). The first frame assembly 402 may further include an upper plate 412,a lower plate 414, and first plurality of support members 416.

The first tubular portion 410 may be mounted to an upper surface 418 ofthe upper plate 412 and may define an aperture 420 extendingtherethrough, which may extend in an at least substantially verticaldirection. The upper plate 412 may be disposed above the lower plate 414with the first plurality of support members 416 connected to andextending between the upper plate 412 and lower plate 414. The upperplate 412 may further have a hole 422, as shown in FIG. 4B, extendingtherethrough, which may be at least substantially aligned with theaperture 420 extending through the first tubular portion 410.

The first adjustment mechanism 406 may be disposed between the upperplate 412 and lower plate 414 of the first frame assembly 402. The firstadjustment mechanism 406 may include an upper plate portion 424, a lowerplate portion 426, and a second plurality of support members 428. Theupper plate portion 424 of the first adjustment mechanism 406 may bedisposed adjacent to a lower surface of the upper plate 412 of the firstframe assembly 402. The lower plate portion 426 of the first adjustmentmechanism 406 may be disposed adjacent to an upper surface of the lowerplate 414 of the first frame assembly 402. In some embodiments, thelower plate portion 426 may include a first plurality of guide recesses430 defined in an upper surface thereof. Each guide recess 430 of thefirst plurality of guide recesses 430 may define a respective pathway inthe upper surface of the lower plate portion 426 of the first adjustmentmechanism 406. In some embodiments, the upper plate portion 424 of thefirst adjustment mechanism 406 may also include guide recesses (notshown). The second plurality of support members 428 may be connected toand may extend between the upper plate portion 424 and lower plateportion 426. The first adjustment mechanism 406 may be rotatablerelative to the first frame assembly 402 of the chip collection tube 110and about a central longitudinal axis 434 of the chip collection tube110.

The first plurality of adjustable walls 404 may be disposed within aninterior 436 of the first frame assembly 402 and may extend from thelower plate portion 426 of the first adjustment mechanism 406, throughthe hole 422 in the upper plate 412, and into the aperture 420 of thefirst tubular portion 410 of the first frame assembly 402. In someembodiments, at least a portion of the first plurality of adjustablewalls 404 may extend out of an upper longitudinal end of the firsttubular portion 410 of the first frame assembly 402. In other words,portions of the first plurality of adjustable walls 404 may extend abovethe first tubular portion 410 of the first frame assembly 402.

Each adjustable wall 404 of the first plurality of adjustable walls 404may include a pivot side 442 and a swing side 444. Each adjustable wall404 may further include at least one inner surface 446. The at least oneinner surface 446 of each adjustable wall 404 may face the interior 436of the first frame assembly 402 of the chip collection tube 110 and mayat least partially define the inner diameter 408 of chip collection tube110, as shown in FIG. 4B.

The pivot side 442 of each adjustable wall 404 of the first plurality ofadjustable walls 404 may be rotatably mounted to the lower plate 414 ofthe first frame assembly 402, and each adjustable wall 404 of the firstplurality of adjustable walls 404 may be rotatable about an axis that isat least substantially parallel to the central longitudinal axis 434 ofthe chip collection tube 110. For example, the first frame assembly 402may include a first plurality of rod members 438 extending from thelower plate 414 to the upper plate 412 thereof, and the pivot side 442of each adjustable wall 404 of the first plurality of adjustable walls404 may be rotatably coupled to a respective rod member 438 of the firstplurality of rod members 438, and each adjustable wall 404 of the firstplurality of adjustable walls 404 may be rotatable about a respectiverod member 438. Consequently, a swing side 444 of each adjustable wall404 may be rotatable into the interior 436 of the first frame assembly402, as shown in FIG. 4C. As a result, the at least one inner surface446 of each adjustable wall 404 of the first plurality of adjustablewalls 404 may be movable at least generally radially toward the centrallongitudinal axis 434 of the chip collection tube 110, effectivelychanging the inner diameter 408 of the chip collection tube 110.

In some embodiments, the at least one inner surface 446 of eachadjustable wall 404 of the first plurality of adjustable walls 404 mayhave an at least substantially curved shape. In other words, the atleast one inner surface 446 of each adjustable wall 404 may have atleast some curvature (e.g., may be concave). For example, a curvature ofthe at least one inner surface 446 of each adjustable wall 404 may atleast substantially match a curvature of a maximum inner diameter 408 ofthe chip collection tube 110. In other embodiments, the curvature of theat least one inner surface 446 of each adjustable wall 404 may at leastsubstantially match a curvature of a minimum inner diameter 408 of thechip collection tube 110. In other embodiments, the curvature of the atleast one inner surface 446 of each adjustable wall 404 may at leastsubstantially match a curvature of an intermediate inner diameter 408 ofthe chip collection tube 110.

Referring to FIG. 4A, each adjustable wall 404 of the first plurality ofadjustable walls 404 may include a pin member 450 extending from alongitudinal end of each adjustable wall 404. The pin member 450 mayextend into a respective guide recess 430 of the first plurality ofguide recesses 430 defined in an upper surface of the lower plateportion 426 of the first adjustment mechanism 406 and may be movablealong the pathway of the respective guide recess 430 of the firstplurality of guide recesses 430. The pathway of each guide recess 430 ofthe first plurality of guide recesses 430 may cause a respectiveadjustable wall 404 to rotate about the pivot side 442 of the respectiveadjustable wall 404 as the pin member 450 moves along the pathway.

Referring to FIGS. 4A, 4B, and 4C together, in operation, when changingthe inner diameter 408 of a chip collection tube 110 of the plurality ofchip collection tubes 110, the first plurality of adjustable walls 404may be rotated into or out of the interior 436 of first frame assembly402 of the chip collection tube 110 by rotating the first adjustmentmechanism 406 relative to the first frame assembly 402 and about thecentral longitudinal axis 434 of the chip collection tube 110. As thefirst adjustment mechanism 406 is rotated relative to the first frameassembly 402 each pin member 450 of each adjustable wall 404 of thefirst plurality of adjustable walls 404 may move along a respectivepathway of a respective guide recess 430 of the first plurality of guiderecesses 430. As each pin member 450 moves along a respective pathway ofa respective guide recess 430 of the first plurality of guide recesses430, the first plurality of adjustable walls 404 may rotate about thepivot sides 442 of the first plurality of adjustable walls 404. As aresult, the swing sides 444 of the first plurality of adjustable walls404 may be rotated into the interior 436 of the first frame assembly 402of the chip collection tube 110 and toward the central longitudinal axis434 of the chip collection tube 110. Also as a result, the at least oneinner surface 446 of the first plurality of adjustable walls 404 may bemoved toward the central longitudinal axis 434 of the chip collectiontube 110, effectively changing (e.g., decreasing) the inner diameter 408of the chip collection tube 110. Thus, the inner diameter 408 of thechip collection tube 110 may be changed (e.g., adjusted) by rotating thefirst adjustment mechanism 406 relative to first frame assembly 402 ofthe chip collection tube 110.

In some embodiments, when the first plurality of adjustable walls 404 isrotated into the interior 436 of the first frame assembly 402, the innerdiameter 408 of the chip collection tube 110 defined by the innersurfaces 446 of the first plurality of adjustable walls 404 may not becentered about (e.g., may be offset from) the central longitudinal axis434 of the chip collection tube 110. In other embodiments, when thefirst plurality of adjustable walls 404 is rotated into the interior 436of the first frame assembly 402, the inner diameter 408 of the chipcollection tube 110 may be at least substantially centered about thecentral longitudinal axis 434 (e.g., centerline) of the chip collectiontube 110.

Referring still to FIGS. 4A, 4B, and 4C together, the inner diameter 408of a chip collection tube 110 may be adjusted to accommodate differentsized chips 208. Thus, the chip collection tubes 110 of the presentdisclosure may provide an advantage by removing a need to have multipledifferent sized collection tubes on a single chip sorting device 100 inorder to accommodate differing sized chips 208. Furthermore, the chipcollection tubes 110 of the present disclosure may provide an advantageof negating a need to disassemble chip sorting devices and exchangecollection tubes in order to accommodate different size chips 208.Moreover, the chip collection tubes 110 of the present disclosure mayenable a chip sorting device 100 to be used for more than one chip sizesuch that the chip sorting device 100 is not limited to a certain sizeof chip 208. The chip collection tubes 110 of the present disclosure maybe used as universal collection tubes that can accommodate a range ofchip sizes. Accordingly, a chip sorting device 100 utilizing the chipcollection tubes 110 of the present disclosure may be used in a widervariety of applications (e.g., games) without require any components tobe exchanged. Furthermore, chip sorting devices 100 utilizing the chipcollection tubes 110 of the present disclosure may quickly be switchedfrom sorting certain chip sizes to sorting different chip sizes ascompared to conventional chip sorting devices currently available.Therefore, the chip collection tubes 110 increase the range of chips 208and, as a result, the range of applications (e.g., games) that can beadministered at a table to which a chip sorting device 100 is positionedunder. Moreover, the chip collection tubes 110 of the present disclosuremay reduce costs in producing and manufacturing chip sorting devices 100for sorting mixtures of chips 208 having differing sizes becausedifferent chip collection tubes for different sizes of chips 208 willnot have to be produced and manufactured. Rather, a plurality of thechip collection tubes 110 of the present disclosure can be used and eachadjusted as needed to accommodate the different sizes of chips 208.

In some embodiments, the inner diameter 408 of the chip collection tube110 may be manually adjusted by a user by rotating the first adjustmentmechanism 406 relative the first frame assembly 402 and about thecentral longitudinal axis 434 of the chip collection tube 110. Forexample, the first adjustment mechanism 406 may have a plurality ofpositions that correlate to different chip 208 sizes, and a user canorient the first adjustment mechanism 406 in one of the plurality ofpositions depending on the size of the chips 208 (FIG. 2) to be sorted.In other embodiments, the inner diameter 408 of the chip collection tube110 may be automatically adjusted by the chip sorting device 100 (FIG.1). For example, the chip sorting device 100 (FIG. 1) may include asensing element that senses a size of a chip 208 (FIG. 2) to be sorted,and based on the size, a control unit of the chip sorting device 100(FIG. 1) may actuate the first adjustment mechanism 406 of the chipcollection tube 110 to adjust the inner diameter 408 of the chipcollection tube 110 to match the size of the chip 208 (FIG. 2) to besorted. In yet other embodiments, the inner diameter 408 of the chipcollection tube 110 may not have to be adjusted by a user or a controlunit. Rather, in some embodiments, the inner diameter 408 mayautomatically adjust to an appropriate size when a chip 208 (FIG. 2) isinserted into the chip collection tube 110 by a chip ejection unit 108.For example, the first plurality of adjustable walls 404 may bepositioned at (e.g., biased toward) a minimum inner diameter 408 of thechip collection tube 110, and when a chip 208 (FIG. 2) is inserted inthe chip collection tube 110 by a chip ejection unit 108, if the chip208 (FIG. 2) has a larger diameter than the minimum inner diameter 408of the chip collection tube 110, the chip 208 (FIG. 2) will pressagainst the at least one inner surfaces 446 of the first plurality ofadjustable walls 404 and expand the inner diameter 408 of the chipcollection tube 110 until the chip 208 (FIG. 2) fits within the chipcollection tube 110. In other words, the chip 208 (FIG. 2) will pressagainst the at least one inner surface 446 of the first plurality ofadjustable walls 404 and will cause the first plurality of adjustablewalls 404 to rotate about the pivot sides 442 of the first plurality ofadjustable walls 404, and the inner diameter 408 of the chip collectiontube 110 may be increased. Thus, in some embodiments, any need tomanually adjust the inner diameters 408 of the chip collection tubes 110may be at least substantially eliminated.

It is understood that while a chip sorting device 100 (FIG. 1) may havea plurality of chip collection tubes 110, the inner diameters 408 of thechip collection tubes 110 may vary in size one to another. Furthermore,in some embodiments, the plurality of chip collection tubes 110 of thechip sorting device 100 (FIG. 1) may all have the same inner diameter408.

FIG. 5A is a perspective view of a plunger assembly 502 of the chipsorting device 100 (FIG. 1). The plunger assembly 502 may include aplunger 504 and an actuating assembly 506. The plunger 504 may beoperably coupled to the actuating assembly 506. The plunger 504 mayinclude a head portion 508 and an elongated portion 510. The headportion 508 may be connected to a longitudinal end of the elongatedportion 510. The head portion 508 of the plunger 504 may include aplurality of arms 512 extending radially away from the head portion 508.

Referring to FIGS. 5A and 4A together, the plunger assembly 502 may bemounted to a bottom surface 448 of the lower plate 414 of the firstframe assembly 402 of the chip collection tube 110, and the actuatingassembly 506 may cause the plunger 504 of the plunger assembly 502 topass back and forth through a longitudinal length of the chip collectiontube 110. In some embodiments, the plunger 504 of the plunger assembly502 may pass through the interior 436 of the first frame assembly 402 ofthe chip collection tube 110 and push any chips 208 (FIG. 2) that mightbe collected in the chip collection tube 110 up to a table surface of atable to which the chip sorting device 100 (FIG. 1) may be positionedunder. In some embodiments, the actuating assembly 506 may bepneumatically actuated to cause the plunger 504 to pass through theinterior 436 of the first frame assembly 402 of the chip collection tube110. In other embodiments, the actuating assembly 506 may beelectronically actuated to cause the plunger 504 to pass through theinterior 436 of the first frame assembly 402 of the chip collection tube110. For example, in some embodiments the actuating assembly 506 mayinclude a solenoid assembly that causes the plunger 504 to pass throughthe interior 436 of the first frame assembly 402 of the chip collectiontube 110. In some embodiments, the actuating assembly 506 may include adrive belt 520 to which the plunger 504 is operably coupled and by whichthe actuating assembly 506 may pass the plunger 504 through the interior436 of the first frame assembly 402 of the chip collection tube 110. Insome embodiments, the drive belt 520 may be at least partially formedfrom a nonmetal material (e.g., not a metal chain drive belt). Forexample, the drive belt 520 may be formed from a flexible polymermaterial that, as noted above with respect to drive belt 216, may befiber-reinforced and that may require little to no maintenance (e.g.,may not require regularly scheduled lubrication).

FIG. 5B is a top side view of a chip collection tube 110 having theplunger 504 of FIG. 5A disposed therein. Referring to FIGS. 5B and 4Atogether, in some embodiments, the arms 512 of the plunger 504 and thefirst plurality of adjustable walls 404 enable the plunger 504 to passthrough the interior 436 of the first frame assembly 402 of the chipcollection tube 110 and push any chips 208 (FIG. 2) that might becollected in the chip collection tube 110 up to a table surfacethroughout a range of inner diameters 408 (FIG. 4B) of the chipcollection tube 110. In other words, the arms 512 of the plunger 504 andthe first plurality of adjustable walls 404 enable the plunger 504 topass through the interior 436 of the chip collection tube 110 even whenthe first plurality of adjustable walls 404 are presently rotated intothe interior 436 of the chip collection tube 110 and the inner diameter408 of the chip collection tube 110 is presently decreased. Stated inyet another way, the arms 512 of the plunger 504 and the first pluralityof adjustable walls 404 enable the plunger 504 to pass through theinterior 436 of the chip collection tube 110 regardless of the innerdiameter 408 of the chip collection tube 110. For example, eachadjustable wall 404 of the first plurality of adjustable walls 404 of achip collection tube 110 may include an indented portion 514, which maycorrelate to a respective arm 512 of the plurality of arms 512 of thehead portion 508 of the plunger 504 and that may be shaped toaccommodate a respective arm 512 of the head portion 508 of the plunger504. In other words, the indented portion 514 of each adjustable wall404 may define a passage 516 through which a respective arm 512 of theplurality of arms 512 may pass through even when the respective arm 512of the plurality of arms 512 extends out a distance from the centrallongitudinal axis 434 that is farther than a distance from the centrallongitudinal axis 434 to an inner surface 446 of the adjustable wall 404(e.g., the respective arm 512 extends past the inner diameter 408).Thus, the plunger 504 may be used to push chips 208 (FIG. 2) collectedin the chip collection tube 110 up to a table surface even when theinner diameter 408 (FIG. 4B) of the chip collection tube 110 is changed.Furthermore, in such an embodiment, when the inner diameter 408 (FIG.4B) of the chip collection tube 110 is changed, the plunger 504 does notrequire any adjustment.

FIG. 5C is a perspective view of a plunger assembly 502 of FIG. 5A in anextended position. As shown in FIG. 5C, in some embodiments, the headportion 508 of the plunger 504 of the plunger assembly 502 may furtherinclude an extension portion 518. The extension portion 518 may extendfarther than the rest of the head portion 508 of the plunger 504 (e.g.,plurality of arms 512). For example, when the plunger 504 is used topush chips 208 out of chip collection tube 110 (FIG. 4A) and up to atable surface, the plurality of arms 512 of the head portion 508 of theplunger 504 may stay below the table surface while the extension portion518 may extend until at least a portion of the extension portion 518 issubstantially flush with or above the table surface.

FIG. 6A is a perspective view of the chip collection tube 110 of FIG. 4Awith additional portions of the chip sorting device 100 shown forclarity. As shown in FIG. 6A, the chip collection tube 110 may furtherinclude a second frame assembly 602, a second plurality of adjustablewalls 604, a second adjustment mechanism 606, and a chip outlet portion608. FIG. 6B is a perspective view of the second frame assembly 602,second plurality of adjustable walls 604, and second adjustmentmechanism 606 with other portions removed to more clearly show thestructure of the second frame assembly 602. FIG. 6C is a top side viewof the second frame assembly 602, second plurality of adjustable walls604, and second adjustment mechanism 606 of FIG. 6B. Referring to FIGS.6A-6C together, the second frame assembly 602 of the chip collectiontube 110 may be similar to the first frame assembly 402 of the chipcollection tube 110 and may include a second tubular portion 610, anupper plate 612, a lower plate 614, and third plurality of supportmembers 616. The second tubular portion 610 may be mounted to the upperlongitudinal end of the first tubular portion 410 of the first frameassembly 402 of chip collection tube 110 and may define an aperture 634extending therethrough, which may extend in an at least substantiallyvertical direction (e.g., along the central longitudinal axis 434 (FIG.4A)). The lower plate 614 may be mounted above the second tubularportion 610 of the second frame assembly 602. The upper plate 612 may bedisposed above the lower plate 614 with the third plurality of supportmembers 616 connected to and extending between the upper plate 612 andlower plate 614. The upper plate 612 and lower plate 614 may each have ahole 618 a, 618 b, as shown in FIG. 6B, extending therethrough. Both ofthe holes 618 a, 618 b may be at least substantially aligned with theaperture 420 (FIG. 4A) extending through the first tubular portion 410of the first frame assembly 402. In some embodiments, the upper plate612 may include a first plurality of protrusions 620 that extendradially inward from an edge of the upper plate 612 defining the hole618 a extending through the upper plate 612. In some embodiments, thelower plate 614 may include a second plurality of protrusions 622 thatextend radially inward from an edge of the lower plate 614 defining thehole 618 b extending through the lower plate 614. The first and secondplurality of protrusions 620, 622 may prevent chips 208 (FIG. 2) fromfalling off the head portion 508 (FIG. 5A) of the plunger 504 (FIG. 5A)and becoming stuck between the plunger 504 (FIG. 5A) and inner surfaces624 of the second plurality of adjustable walls 604. For example, thefirst and second plurality of protrusions 620, 622 may prevent chips 208(FIG. 2) from falling off the head portion 508 (FIG. 5A) of the plunger504 (FIG. 5A) when the second plurality of adjustable walls 604 is notadjusted properly or when sorting an irregular sized chip.

The second adjustment mechanism 606 may be disposed between the upperplate 612 and lower plate 614 of the second frame assembly 602. Thesecond adjustment mechanism 606 may include a lower plate portion 626.The lower plate portion 626 of the second adjustment mechanism 606 maybe disposed adjacent to an upper surface 628 of the lower plate 614 ofthe second frame assembly 602. In some embodiments, the lower plateportion 626 may include a second plurality of guide recesses 630 definedin an upper surface 632 thereof. Each guide recess 630 of the secondplurality of guide recesses 630 may define a respective pathway in theupper surface 632 of the lower plate portion 626 of the secondadjustment mechanism 606. The lower plate portion 626 may furtherinclude a hole 618 c extending therethrough. The hole 618 c may be atleast substantially aligned with the holes 618 a, 618 b extendingthrough the upper and lower plates 612, 614 of the second frame assembly602 and the aperture 634 extending through the second tubular portion610 of the second frame assembly 602. The lower plate portion 626 of thesecond adjustment mechanism 606 may include a third plurality ofprotrusions 636 that extend radially inward from an edge of the lowerplate portion 626 defining the hole 618 c extending through the lowerplate portion 626. Similar to the first and second plurality ofprotrusions 620, 622, the third plurality of protrusions 636 may assistin preventing chips 208 (FIG. 2) from falling off the head portion 508(FIG. 5A) of the plunger 504 (FIG. 5A) and becoming stuck between theplunger 504 (FIG. 5A) and the inner surfaces 624 of the second pluralityof adjustable walls 604. The second adjustment mechanism 606 may berotatable relative to the second frame assembly 602 of the chipcollection tube 110 and about the central longitudinal axis 434 (FIG.4A) of the chip collection tube 110.

Referring to FIG. 6A, the chip outlet portion 608 of the chip collectiontube 110 may include an upper rim 638, a chip outlet hole 640, and aflange 642. The chip outlet portion 608 may be oriented above the secondframe assembly 602 of the chip collection tube 110 and may be positionedproximate a table surface of a table to which the chip sorting device100 (FIG. 1) may be positioned beneath. The upper rim 638 may define thechip outlet hole 640 and may include an upper surface 644 configured tobe at least substantially flush with the table surface of the table. Theflange 642 may extend at least partially across the chip outlet hole 640and may open and allow chips 208 (FIG. 2) to pass through the chipoutlet hole 640 when the plunger 504 (FIG. 5A) of the plunger assembly502 (FIG. 5A) pushes the chips 208 (FIG. 2) up to the table surface.

Referring again to FIGS. 6A-6C together, the second plurality ofadjustable walls 604 may be disposed within an interior 646 of thesecond frame assembly 602 and may extend from the second tubular portion610 and through the holes 618 a, 618 b in the upper and lower plates612, 614 of the second frame assembly 602. In some embodiments, at leastsome of the second plurality of adjustable walls 604 may extend past theupper plate 612 of the second frame assembly 602. In other words,portions of the second plurality of adjustable walls 604 may extendabove the upper plate 612 of the second frame assembly 602.

Each adjustable wall 604 of the second plurality of adjustable walls 604may include a pivot side 648 and a swing side 650. The at least oneinner surface 624 of each adjustable wall 604 may face the interior 646of the second frame assembly 602 of the chip collection tube 110 and mayat least partially define the inner diameter 408 (FIG. 4B) of the chipcollection tube 110. In some embodiments, each adjustable wall 604 ofthe second plurality of adjustable walls 604 may include at least oneprojection 652 extending at least generally radially inward from the atleast one inner surface 624 of each adjustable wall 604. The at leastone projection 652 of each adjustable wall 604 of the second pluralityof adjustable walls 604 may further assist in keeping chips 208 (FIG. 2)from falling off the head portion 508 (FIG. 5A) of the plunger 504 (FIG.5A) and becoming stuck between the plunger 504 (FIG. 5A) and the innersurfaces 624 of the second plurality of adjustable walls 604.Furthermore, in some embodiments, each adjustable wall 604 of the secondplurality of adjustable walls 604 may include at least one slot aperture654 defined therein. The at least one slot aperture 654 of eachadjustable wall 604 of the second plurality of adjustable walls 604 mayreceive the first and second plurality of protrusions 620, 622 of theupper plate 612 and lower plate 614 of the second frame assembly 602 andthe third plurality of protrusions 636 of the lower plate portion 626 ofthe second adjustment mechanism 606. The at least one slot aperture 654may permit the first, second, and third protrusions 620, 622, 636 tocontinue to prevent chips 208 (FIG. 2) from becoming stuck between theplunger 504 (FIG. 5A) and inner surfaces 624 of the second plurality ofadjustable walls 604 even when the second plurality of adjustable walls604 is adjusted to define larger inner diameters 408 (FIG. 4B).

The pivot side 648 of each adjustable wall 604 of the second pluralityof adjustable walls 604 may be rotatably mounted to the lower plate 614of the second frame assembly 602, and each adjustable wall 604 may berotatable about an axis that is at least substantially parallel to thecentral longitudinal axis 434 (FIG. 4A) of the chip collection tube 110.For example, the second frame assembly 602 may include a secondplurality of rod members 656 extending from the lower plate 614 to theupper plate 612 thereof, and the pivot side 648 of each adjustable wall604 of the second plurality of adjustable walls 604 may be rotatablycoupled to a respective rod member 656 of the second plurality of rodmembers 656, and each adjustable wall 604 of the second plurality ofadjustable walls 604 may be rotatable about a respective rod member 656.Consequently, a swing side 650 of each adjustable wall 604 may berotatable into the interior 646 of the second frame assembly 602.Accordingly, the at least one inner surface 624 of each adjustable wall604 may be movable at least generally radially toward the centrallongitudinal axis 434 (FIG. 4A) of the chip collection tube 110,effectively changing the inner diameter 408 (FIG. 4B) of the chipcollection tube 110.

Referring to FIG. 6B, each adjustable wall 604 of the second pluralityof adjustable walls 604 may include a pin member 658 extending from alongitudinal end of each adjustable wall 604 of the second plurality ofadjustable walls 604. The pin member 658 may extend into a respectiveguide recess 630 of the second plurality of guide recesses 630 definedin upper surface 632 of the lower plate portion 626 of the secondadjustment mechanism 606 and may be movable along the pathway of therespective guide recess 630. The pathway of each guide recess 630 may beshaped and configured to cause a respective adjustable wall 604 torotate about the pivot side 648 of the respective adjustable wall 604 asthe pin member 658 is caused to move along the pathway.

Referring to FIGS. 6A, 6B, and 6C together, in operation, when changingthe inner diameter 408 (FIG. 4B) of the chip collection tube 110, thesecond plurality of adjustable walls 604 may be rotated into or out ofthe interior 646 of second frame assembly 602 of the chip collectiontube 110 by rotating the second adjustment mechanism 606 relative to thesecond frame assembly 602 and about the central longitudinal axis 434(FIG. 4A) of the chip collection tube 110. As the second adjustmentmechanism 606 is rotated relative to the second frame assembly 602 eachpin member 658 of each adjustable wall 604 of the second plurality ofadjustable walls 604 may be caused to move along a respective pathway ofa respective guide recess 630 of the second plurality of guide recesses630. As each pin member 658 is caused to move along a respectivepathway, a respective adjustable wall 604 of the second plurality ofadjustable walls 604 may be caused to rotate about the pivot side 648 ofthe adjustable wall 604. As a result, the swing side 650 of theadjustable wall 604 may be rotated into the interior 646 of the secondframe assembly 602 of the chip collection tube 110 and toward thecentral longitudinal axis 434 (FIG. 4A) of the chip collection tube 110.Furthermore, as a result, the at least one inner surface 624 and the atleast one projection 652 of the adjustable wall 604 may be moved towardthe central longitudinal axis 434 of the chip collection tube 110,effectively changing (e.g., decreasing) the inner diameter 408 (FIG. 4B)of the chip collection tube 110. Thus, the inner diameter 408 (FIG. 4B)of the chip collection tube 110 may be changed (e.g., adjusted) byrotating the second adjustment mechanism 606 relative to second frameassembly 602 of the chip collection tube 110. In some embodiments, whenthe second plurality of adjustable walls 604 is rotated into theinterior 646 of the second frame assembly 602, the inner diameter 408(FIG. 4B) of the chip collection tube 110 defined by the inner surfaces624 of the second plurality of adjustable walls 604 may be at leastsubstantially centered about the central longitudinal axis 434 (FIG. 4A)of the chip collection tube 110. In other embodiments, when the secondplurality of adjustable walls 604 is rotated into the interior 646 ofthe second frame assembly 602, the inner diameter 408 (FIG. 4B) of thechip collection tube 110 defined by the inner surfaces 624 of the secondplurality of adjustable walls 604 may not be centered about the centrallongitudinal axis 434 (FIG. 4A) of the chip collection tube 110.

In some embodiments, the first plurality of adjustable walls 404 and thesecond plurality of adjustable walls 604 may rotate in unison. In otherwords, the first plurality of adjustable walls 404 and the secondplurality of adjustable walls 604 may define at least substantially thesame inner diameter 408 (FIG. 4B) of the chip collection tube 110 at thesame time. For example, the first adjustment mechanism 406 and thesecond adjustment mechanism 606 may be coupled such that rotating one ofthe first adjustment mechanism 406 or the second adjustment mechanism606, rotates the other.

In some embodiments, the chip collection tube 110 may have only a firstplurality of adjustable walls 404 and may not include a second pluralityof adjustable walls 604. In such embodiments, the first plurality ofadjustable walls 404 may extend from the lower plate 414 of the firstframe assembly 402 to the chip outlet portion 608 of the chip collectiontube 110. Furthermore, in such embodiments, the chip collection tube 110may include only a first adjustment mechanism 406.

FIG. 7A is a perspective view of the chip hopper 104 of a chip sortingdevice 100 (e.g., the chip sorting device 100 shown in FIGS. 1 and 2).The chip hopper 104 may include a chip chamber 702 and a base plate 704.The chip chamber 702 may include a separating wheel base 706 having aplurality of circular holes 708 defined therein. Each of the pluralityof circular holes 708 defined in the separating wheel base 706 mayreceive at least one chip 208. The chip chamber 702 may be mounted forrotation about a central axis 707 over an upper surface 710 of the baseplate 704, and the chip chamber 702 may be rotatable relative to thebase plate 704. The base plate 704 may include a linear side 712 and maybe oriented with the linear side 712 of the base plate 704 beingimmediately adjacent and extending along a portion of the chip conveyorunit 106 of the chip sorting device 100 (FIG. 1). A portion of the chipchamber 702 may extend past the linear side 712 of the base plate 704and over the chip conveyor unit 106 of the chip sorting device 100(FIG. 1) in order to supply chips 208 from the chip chamber 702 onto thechip conveyor unit 106.

In operation, a plurality of chips 208 may be inserted into the chipchamber 702 of the chip hopper 104 and the chip chamber 702 may rotaterelative to the base plate 704. For example, the chip sorting device 100(FIG. 1) may be positioned beneath a table, with the chip chamber 702 ofthe chip hopper 104 exposed (e.g., oriented adjacent to an edge of thetable or positioned in an opening in the table). At certain intervalsduring game play, an operator (not shown) may move a plurality of chips208 from a surface of the table to the chip chamber 702 to be sorted bythe chip sorting device 100 (FIG. 1). In some embodiments, the chipsorting device 100 may be separate from the table, such as in a countingroom of a casino (not shown).

The chips 208 may come to rest at a bottom of the chip chamber 702 andmay be urged (e.g., by gravity and/or by a chip displacement device 738)to fall into individual circular holes 708 of the plurality of circularholes 708 of the separating wheel base 706. For example, the chipdisplacement device 738 may rotate relative to chip chamber 702 andseparating wheel base 706 and may include displacement members 740 tomove chips 208 (e.g., displace, stir, etc.) within the chip chamber 702and urge the chips 208 into the plurality of circular holes 708 of theseparating wheel base 706.

As the chips 208 are urged into the plurality of circular holes 708, thechip chamber 702 may be rotated and the separating wheel base 706 mayslide the chips 208 within the plurality of circular holes 708 along acircumferential path on the upper surface 710 of the base plate 704until the chips 208 are moved past the linear side 712 of the base plate704 and over the chip conveyor unit 106. The chips 208 may then bedelivered into a chip well 206 of an articulated link unit 204 of thechip conveyor unit 106. For example, the chips 208 may fall through theplurality of circular holes 708 and into a chip well 206 of anarticulated link unit 204 of the chip conveyor unit 106. The chips 208may then be delivered by the chip conveyor unit 106 to the plurality ofchip ejection units 108 (FIG. 1) and plurality of chip collection tubes110 (FIG. 1).

FIG. 7B is a perspective view of the chip hopper 104 of FIG. 7A with thechip chamber 702 removed to more clearly show the structure of the baseplate 704. As shown in FIG. 6B, the base plate 704 may include a cutout714 extending through base plate 704, and the chip hopper 104 mayfurther include a relief mechanism 716 disposed in the cutout 714. Thecutout 714 may extend from the linear side 712 of the base plate 704into the base plate 704, and the relief mechanism 716 disposed in thecutout 714 may be oriented immediately adjacent to the chip conveyorunit 106 (e.g., such that a linear side of the relief mechanism 716 maybe coextensive with the linear side 712 of the relief mechanism 716).The cutout 714 may be oriented along the circumferential path alongwhich the separating wheel base 706 transports chips 208.

The relief mechanism 716 may include a top plate 718, a pusher 720, andan actuator 721. The relief mechanism 716 may act to remove chips 208that become jammed (e.g., stuck) between the chip chamber 702 and theupper surface 710 of the base plate 704 of the chip hopper 104. Forexample, chips 208 may become stuck between the chip chamber 702 and theupper surface 710 of the base plate 704 by slipping at least partiallybeneath the chip chamber 702 and/or becoming wedged between theseparating wheel base 706 and the base plate 704. Chips 208 may becaused to slip beneath the chip chamber 702 for many reasons such as,for example, when the chips 208 are misshaped due to normal wear andtear or when the chips 208 are dirty due to use. Chips 208 that becomestuck between the chip chamber 702 and base plate 704 of the chip hopper104 may continue to move with the chip chamber 702 as the chip chamber702 rotates relative to the base plate 704 of the chip hopper 104.

The relief mechanism 716 may be oriented in the cutout 714 of the baseplate 704 such that a top surface 722 of the top plate 718 of the reliefmechanism 716 is as least substantially flush with the upper surface 710of the base plate 704. The top plate 718 of the relief mechanism 716 mayhave substantially a same shape as the cutout 714 of the base plate 704,and the top plate 718 may at least substantially fill the cutout 714 ofthe base plate 704. The top plate 718 may include a base region 724, aplurality of teeth 726, and a plurality of slot voids 728 definedbetween the teeth 726. The plurality of teeth 726 may extend from thebase region 724, and each of the plurality of slot voids 728 may bedefined between adjacent teeth 726 of the plurality of teeth 726. Therelief mechanism 716 may be oriented in the cutout 714 of the base plate704 such that the teeth 726 of the top plate 718 of the relief mechanism716 extend toward the chip conveyor unit 106 and in a direction at leastgenerally perpendicular to the straight pathway portion of the chipconveyor unit 106. For example, the top plate 718 may have a comb-likestructure.

The pusher 720 may be oriented generally beneath the top plate 718 andmay include a plurality of fingers 730 that extends into the pluralityof slot voids 728 between adjacent teeth 726 of the plurality of teeth726 of the top plate 718 of the relief mechanism 716. The plurality offingers 730 may slide along the longitudinal length of the slot voids728 and grasp any chips 208 that may be present on the top surface 722of the top plate 718 of the relief mechanism 716.

Referring to FIGS. 7A and 7B together, the relief mechanism 716 may beable to increase a space between the chip chamber 702 and the topsurface 722 of the top plate 718 of the relief mechanism 716. Forexample, at least a portion of the top plate 718 may be lowered relativeto the base plate 704 of the chip hopper 104 (e.g., at least a portionof the relief mechanism 716 may move away from the separating wheel base706). In some embodiments, the entire top plate 718 of the reliefmechanism 716 may be lowered relative to the base plate 704 of the chiphopper 104. In other embodiments, only a portion of the top plate 718may be lowered relative to the base plate 704 of the chip hopper 104.For example, the top plate 718 of the relief mechanism 716 may berotated (e.g., swiveled, swung, pivoted) downward about the base region724 of the top plate 718 of the relief mechanism 716 relative to thebase plate 704 of the chip hopper 104 such that the teeth 726 of the topplate 718 are rotated downward and away from the chip chamber 702 of thechip hopper 104 (e.g., rotated away from the separating wheel base 706).

In some embodiments, the top plate 718 of the relief mechanism 716 maybe biased toward a position wherein the top surface 722 of the top plate718 is at least substantially flush with the upper surface 710 of thebase plate 704 of the chip hopper 104 (i.e., a non-lowered position). Insuch embodiments, any chips 208 that become stuck between the chipchamber 702 and the upper surface 710 of the base plate 704 of the chiphopper 104 may cause (e.g., force) the top plate 718 of the reliefmechanism 716 to lower relative to the base plate 704 of the chip hopper104. In other embodiments, the top plate 718 of the relief mechanism 716may be lowered by the actuator 721 and the relief mechanism 716 mayfurther include a sensor to sense when a chip 208 is stuck between thechip chamber 702 and the upper surface 710 of the base plate 704 of thechip hopper 104. In such embodiments, the actuator 721 may lower the topplate 718 of the relief mechanism 716 when the sensor senses a stuckchip 208. In yet other embodiments, the top plate 718 of the reliefmechanism 716 may be biased toward a non-lowered position and may belowered (e.g., forced downward away from the chip hopper 104) by a stuckchip 208 but may be further lowered by the actuator 721. For example,when the top plate 718 is pushed down by a stuck chip 208, the actuator721 may cause the top plate 718 to further lower relative to the baseplate 704 of the chip hopper 104. Regardless of how the top plate 718 islowered, when a chip 208 that is stuck between the chip chamber 702 andthe base plate 704 is moved over the top plate 718 of the reliefmechanism 716 and the top plate 718 is lowered, the chip 208 may bemoved into a chip well 206 of the chip conveyor unit 106 to avoid anyfurther jamming of the chip chamber 702 (e.g., halting rotation of thechip chamber 702).

Furthermore, when the top plate 718 of the relief mechanism 716 islowered, the plurality of fingers 730 of the pusher 720 may extendthrough the slot voids 728 of the top plate 718 and above the topsurface 722 of the top plate 718 of the relief mechanism 716 in order tograsp chips 208 that may be present on the top surface 722 of the topplate 718 of the relief mechanism 716. Furthermore, when the top plate718 of the relief mechanism 716 is lowered, the actuator 721 may movethe plurality of fingers 730 of the pusher 720 along the slot voids 728between the teeth 726 of the top plate 718 to push chips 208 across thetop surface 722 of the top plate 718 and into a chip well 206 of anarticulated link unit 204 of the chip conveyor unit 106. For example,the actuator 721 may move the plurality of fingers 730 of the pusher 720through sweeping motions that include raising the plurality of fingers730 of the pusher 720 above the top surface 722 of the top plate 718near the base region 724 of the top plate 718, sliding the plurality offingers 730 along the longitudinal lengths of the slot voids 728 whilethe plurality of fingers 730 are raised above the top surface 722 of thetop plate 718, and dropping the plurality of fingers 730 beneath the topsurface 722 of the top plate 718 once the plurality of fingers 730reaches the chip conveyor unit 106, and bringing the plurality offingers 730 back to the base region 724 of the top plate 718 while theplurality of fingers 730 is beneath the top surface 722 of the top plate718 of the relief mechanism 716.

The embodiments of the disclosure described above and illustrated in theaccompanying drawings do not limit the scope of the disclosure, which isencompassed by the scope of the appended claims and their legalequivalents. Any equivalent embodiments are within the scope of thisdisclosure. Indeed, various modifications of the disclosure, in additionto those shown and described herein, such as alternative usefulcombinations of the elements described, will become apparent to thoseskilled in the art from the description. Such modifications andembodiments also fall within the scope of the appended claims andequivalents.

What is claimed is:
 1. A chip sorting device, comprising: a chipconveyor unit comprising at least one chip well for transporting chips;at least one chip collection tube having an inner lateral dimension forreceiving at least one chip therein, the at least one chip collectiontube comprising: at least one frame assembly; and at least oneadjustable wall, at least a portion of the at least one adjustable wallbeing rotatable relative to the at least one frame assembly toselectively increase and decrease the inner lateral dimension of the atleast one chip collection tube, the at least one adjustable wallcomprising: a pivot side rotatably mounted to the at least one frameassembly; and at least one inner surface at least partially defining theinner lateral dimension of the at least one chip collection tube, the atleast one inner surface extending from a distalmost portion of the atleast one adjustable wall to the pivot side; and at least one chipejection unit configured and positioned to eject at least one chip fromthe at least one chip well of the chip conveyor unit into the at leastone chip collection tube, wherein the at least one inner surface of theat least one adjustable wall is configured to directly contact the atleast one chip in the at least one chip collection tube.
 2. The chipsorting device of claim 1, wherein the at least one adjustable wallcomprises a swing side configured to be rotated into and out of aninterior of the at least one frame assembly.
 3. The chip sorting deviceof claim 1, wherein the at least one chip collection tube furthercomprises at least one adjustment mechanism rotatably mounted within theat least one frame assembly, and wherein the at least one adjustmentmechanism is configured to cause the at least a portion of the at leastone adjustable wall of the at least one chip collection tube to rotaterelative to the at least one frame assembly to adjust the inner lateraldimension of the at least one chip collection tube.
 4. A chip sortingdevice, comprising: a chip conveyor unit comprising at least one chipwell for transporting chips; at least one chip collection tube having aninner lateral dimension for receiving at least one chip therein, the atleast one chip collection tube comprising: at least one frame assemblycomprising: a first frame assembly; and a second frame assembly mountedabove the first frame assembly, the second frame assembly having aplurality of protrusions extending from the second frame assemblyradially inward toward an interior of the second frame assembly; and atleast one adjustable wall coupled to the at least one frame assembly andat least partially defining the inner lateral dimension of the at leastone chip collection tube, at least a portion of the at least oneadjustable wall being rotatable relative to the at least one frameassembly to selectively increase and decrease the inner lateraldimension of the at least one chip collection tube, wherein the at leastone adjustable wall comprises: a first plurality of adjustable wallsdisposed within an interior of the first frame assembly and at leastpartially defining the inner lateral dimension of the at least one chipcollection tube; and a second plurality of adjustable walls disposedwithin an interior of the second frame assembly and at least partiallydefining the inner lateral dimension of the at least one chip collectiontube, the second plurality of adjustable walls having a plurality ofslot apertures defined therein, the plurality of slot aperturesconfigured to receive the plurality of protrusions extending radiallyinward from the second frame assembly therein; and at least one chipejection unit configured and positioned to eject at least one chip fromthe at least one chip well of the chip conveyor unit into the at leastone chip collection tube.
 5. A chip sorting device, comprising: a chipconveyor unit comprising at least one chip well for transporting chips;at least one chip collection tube having an inner lateral dimension forreceiving at least one chip therein, the at least one chip collectiontube comprising: at least one frame assembly; and at least oneadjustable wall coupled to the at least one frame assembly and at leastpartially defining the inner lateral dimension of the at least one chipcollection tube, at least a portion of the at least one adjustable wallbeing rotatable relative to the at least one frame assembly toselectively increase and decrease the inner lateral dimension of the atleast one chip collection tube; at least one chip ejection unitconfigured and positioned to eject at least one chip from the at leastone chip well of the chip conveyor unit into the at least one chipcollection tube; and a plunger assembly mounted to the at least one chipcollection tube, the plunger assembly comprising: an actuating assembly;and a plunger operably coupled to the actuating assembly and configuredto pass through the at least one chip collection tube to push chips outof the at least one chip collection tube.
 6. The chip sorting device ofclaim 5, wherein the plunger of the plunger assembly comprises: anelongated portion; a head portion attached to a longitudinal end of theelongated portion; and a plurality of arms extending radially away fromthe head portion.
 7. The chip sorting device of claim 6, wherein the atleast one adjustable wall further comprises an indented portioncorrelating to a respective arm of the plurality of arms of the headportion of the plunger and defining a passage through which therespective arm of the plurality of arms of the head portion of theplunger passes when the head portion is moved through the at least onechip collection tube.
 8. The chip sorting device of claim 1, furthercomprising a chip outlet portion located and configured to eject chipsfrom the at least one chip collection tube to a table surface, the chipoutlet portion comprising: an upper rim having an upper surface anddefining a chip outlet hole, the upper surface configured to be mountedat least substantially flush with the table surface; and a flangeextending at least partially across the chip outlet hole and configuredto open to enable chips to pass through the chip outlet hole to thetable surface.
 9. The chip sorting device of claim 1, further comprisinga chip hopper for delivering chips to the chip conveyor unit, the chiphopper comprising: a base plate having a cutout extending through thebase plate; a chip chamber rotatably mounted over the base plate and thechip conveyor unit, the chip chamber having a separating wheel basehaving a plurality of circular holes defined therein, the plurality ofcircular holes configured to receive at least one chip therein; and arelief mechanism disposed within the cutout of the base plate, at leasta portion of the relief mechanism being configured to move away from thechip chamber.
 10. A chip sorting device, comprising: a chip hoppercomprising: a base plate having an upper surface; a chip chamber mountedover the base plate and rotatable about a center axis relative to thebase plate, the chip chamber comprising a separating wheel base defininga plurality of circular holes each configured to receive chips therein,the base plate configured to receive at least some of the chips upon theupper surface during operation of the chip sorting device; and a reliefmechanism having a top plate having a top surface oriented at leastsubstantially flush with the upper surface of the base plate, the reliefmechanism configured to receive at least some of the chips upon the topsurface of the top plate during operation of the chip sorting device,the relief mechanism configured to move away from the chip chamber inorder to create a space between the upper surface of the base plate andat least a portion of the top surface of the top plate of the reliefmechanism; and a chip conveyor unit comprising at least one chip wellconfigured to receive a chip from the chip hopper.
 11. The chip sortingdevice of claim 10, wherein the base plate includes a cutout extendingthrough the base plate and wherein the relief mechanism is disposedwithin the cutout of the base plate and is oriented immediately adjacentto the chip conveyor unit.
 12. A chip sorting device, comprising: a chipconveyor unit comprising at least one chip well; and a chip hopperconfigured to receive a chip from the chip hopper, the chip hoppercomprising: a base plate; a chip chamber mounted over the base plate androtatable about a center axis relative to the base plate, the chipchamber comprising a separating wheel base defining a plurality ofcircular holes each configured to receive at least one chip therein; anda relief mechanism having a top plate having a top surface oriented atleast substantially flush with an upper surface of the base plate, therelief mechanism configured to move away from the chip chamber, the topplate of the relief mechanism comprising: a base region; and a pluralityof teeth extending from the base region toward the chip conveyor unit,the plurality of teeth defining a plurality of slot voids, each slotvoid of the plurality of slot voids being defined between adjacent teethof the plurality of teeth, wherein the relief mechanism furthercomprises a pusher having a plurality of fingers, wherein each finger ofthe plurality of fingers is configured to extend through a respectiveslot void of the plurality of slot voids of the relief mechanism. 13.The chip sorting device of claim 12, wherein the relief mechanismfurther comprises an actuator configured to extend the plurality offingers above the top surface of the top plate of the relief mechanismand to move the plurality of fingers of the pusher along the pluralityof slot voids to push a chip across the top surface of the top plate ofthe relief mechanism and into the at least one chip well of the chipconveyor unit.
 14. The chip sorting device of claim 10, wherein the topplate of the relief mechanism is biased toward a position wherein thetop surface of the top plate is oriented at least substantially flushwith the upper surface of the base plate.
 15. The chip sorting device ofclaim 14, wherein at least a portion of the top plate of the reliefmechanism is configured to move away from the chip chamber of the chiphopper when a chip that is at least partially stuck between the chipchamber and the base plate of the chip hopper passes over the top plateof the relief mechanism.
 16. The chip sorting device of claim 10,further comprising at least one chip collection tube, comprising: atleast one frame assembly; and a plurality of adjustable walls coupled tothe at least one frame assembly and at least partially defining an innerlateral dimension of the at least one chip collection tube, at least aportion of each adjustable wall of the plurality of adjustable wallsbeing rotatable relative to the at least one frame assembly in order toselectively increase and decrease the inner lateral dimension of the atleast one chip collection tube.
 17. A method of setting up a chipsorting device, comprising adjusting an inner lateral dimension of atleast one chip collection tube of the chip sorting device to accommodateat least one chip, wherein adjusting an inner lateral dimension of atleast one chip collection tube to accommodate at least one chipcomprises: rotating an adjustment mechanism of the at least one chipcollection tube relative to a frame assembly of the at least one chipcollection tube; and rotating a plurality of adjustable walls into aninterior of the frame assembly of the at least one chip collection tuberesponsive to rotation of the adjustment mechanism, the plurality ofadjustable walls each including a pivot side, a distalmost end, and aninner surface extending between the pivot side and the distalmost enddefining at least a portion of the inner lateral dimension of the atleast one chip collection tube.
 18. The method of setting up a chipsorting device of claim 17, wherein rotating a plurality of adjustablewalls into an interior of the frame assembly of the at least one chipcollection tube comprises rotating the at least one adjustable wallabout a pivot side of the at least one adjustable wall to move at leastone inner surface of the at least one adjustable wall toward theinterior of the frame assembly.